Drive circuit of active matrix type display device having buffer with parallel connected elemental circuits and manufacturing method thereof

ABSTRACT

An active matrix device with a plurality of column lines formed over a substrate, a plurality of row lines, a plurality of pixels in a matrix form, a plurality of switching elements, a gate driver circuit, a source driver circuit, said source driver circuit including a plurality of analog buffer circuits corresponding to said plurality of column lines, where each of the analog buffer circuits has at least two circuits connected in parallel with respect to a corresponding one of the column lines, each of said circuits comprising at least one thin film transistor, and one of said at least two circuits of one of the analog buffer circuits is positioned in the same line along said column lines as one of said at least two circuits of another one of the analog buffer circuits.

Continuation of prior application Ser. No. 08/974,163 filed Nov. 19, 1997 now abandoned; which itself is a Division of Ser. No. 08/421,440 filed Apr. 13, 1995, now abandoned.

BACKGROUND OF THE INVENTION

The present invention relates to a drive circuit of an active matrix type display device which is composed of thin-film transistors. In particular, the invention relates to a drive circuit of an active matrix type display device in which source followers are used as analog buffers and variations of their characteristics are suppressed.

The active matrix type display device is a display device in which pixels are arranged at intersections of a matrix with every pixel associated with a switching element, and image information is controlled by turning on/off of the switching elements. This type of display device uses, as a display medium, a liquid crystal, plasma, or some other material or state whose optical characteristic (reflectance, refractive index, transmittance, luminous intensity, or the like) can be varied electrically. In the present invention, specifically a field-effect transistor (three-terminal element) having the gate, source and drain is used as the switching element.

In the following description of the invention, a row of a matrix means a structure in which a signal line (gate line) that is disposed parallel with the row concerned is connected to the gate electrodes of transistors of the row concerned. A column means a structure in which a signal line (source line) that is disposed parallel with the column concerned is connected to the source (or drain) electrodes of transistors of the column concerned. A circuit for driving the gate lines is called a gate drive circuit, and a circuit for driving the source lines is called a source drive circuit.

In the gate drive circuit, stages of a shift register corresponding to the number of gate lines in the vertical direction are arranged linearly and interconnected in series to generate signals of vertical scanning timings of the active matrix type display device. In this manner, the thin-film transistors of the active matrix type display device are switched by means of the gate drive circuit.

In the source drive circuit, stages of a shift register corresponding to the number of source lines in the horizontal direction are arranged linearly and interconnected in series to generate horizontal image data of display image data of the active matrix display device. Analog switches are turned on/off by latch pulses that are synchronized with horizontal scanning signals. In this manner, currents are supplied to the thin-film transistors of the active matrix type display device by means of the source drive circuit, to control orientations of liquid crystal cells.

FIG. 9 schematically shows a conventional active matrix type display device. There are two kinds of polycrystalline silicon thin-film transistor manufacturing processes: a high-temperature process and a low-temperature process. In the high-temperature process, polycrystalline silicon is deposited on an insulating film that is formed on a quartz substrate, and a thermally oxidized SiO₂ is formed as a gate insulating film. Thereafter, gate electrodes are formed, N-type or P-type ions are implanted, and source and drain electrodes are formed. Thus, polycrystalline silicon thin-film transistors are manufactured.

In the low-temperature process, silicon is crystallized by two kinds of methods: solid-phase growth and laser annealing. In the solid-phase growth, a polycrystalline silicon film is obtained by subjecting an amorphous silicon film on an insulating film that is formed on a glass substrate to a heat treatment of 600° C. and 20 hours, for example. In the laser annealing, a polycrystalline silicon film is obtained by applying laser light to amorphous silicon on a glass substrate surface to thereby heat-treat only the film surface portion at a high temperature.

In general, crystalline films are obtained by using, one or both of the above two methods.

An SiO₂ film is then formed as a gate insulating film by plasma CVD. Thereafter, gate electrodes are formed, N-type or P-type ions are implanted, and source and drain electrodes are formed. Thus, polycrystalline silicon thin-film transistors are manufactured.

The source drive circuit is a circuit for supplying image data to an active matrix panel of the active matrix type display device by scanning, it vertically, and is composed of a shift register, analog switches that are thin-film transistors, analog, memories that are capacitors, and analog buffers formed of thin-film transistors.

The analog buffer is needed because the analog, memory cannot directly drive the thin-film transistors of the active matrix type display device due to a large load capacitance of the source line.

The thin-film transistor of the analog buffer has a source follower configuration. As shown in FIGS. 6A and 6B, a single thin-film transistor is provided for each data holding control signal line, and the thin-film transistors are so manufactured as to be arranged at regular intervals.

FIG. 6A shows an example of using N-channel thin-film transistors. Alternatively, P-channel thin-film transistors (see FIG. 6 b) or both types of transistors may be used.

The analog buffers that constitute the source drive circuit of the conventional active matrix type display device have the following problem.

Each analog buffer has the single thin-film transistor that has a source follower configuration. When laser annealing is employed as a means for crystallization as described above in the thin-film transistor manufacturing process, a silicon film on a glass substrate is irradiated with band-like laser light of a width L while being scanned with it in the X-axis direction, i.e., horizontally (see FIG. 7A) to crystallize silicon, because there exists no such large-diameter laser device as can irradiate a large-size substrate at one time.

When the illumination is effected while the laser light is moved in the X-direction at a constant length at a time, there occurs an overlap of illumination. Since the width L of the band-like laser light does not necessarily coincide with a pitch d (see FIG. 7B) of the source follower, the illumination laser light quantity varies depending on the position on the silicon film in the laser crystallization step.

Therefore, a positional variation, i.e., variations in characteristics occur in thin-film transistors that are produced from the above silicon film, and the threshold voltage V_(th) varies from one thin-film transistor to another in the range of V_(thL) to V_(thH) depending on the position X on the X-axis (see FIG. 8). The threshold voltage V_(th) has a small value at a position where laser beams overlap with each other, and has a large value where they do not. As a result, there occurs a variation in magnitude of output voltages of the source followers, which directly results in a variation of application voltages to the liquid crystal device.

FIG. 11 shows an application voltage vs. transmittance characteristic of a normally-white liquid crystal device. It is understood that a variation ⊖V_(th) of the threshold voltage V_(th) causes a corresponding variation of the transmittance, which is reflected in a displayed image.

As described above, the output voltages of the source drive circuit undesirably vary depending on positions thereof, resulting in display unevenness of pixels of the active matrix type display device.

SUMMARY OF THE INVENTION

An object of the present invention is to reduce display unevenness of pixels in an active matrix type display device.

In contrast to the conventional device in which a single analog buffer is provided for a data holding control signal for each data line, the present invention is characterized in that a data holding control signal is connected with a plurality of source followers that are connected together in parallel. Further, in accordance with a preferred embodiment of the present invention, the parallel-connected source followers are a combination of at least one source follower that is irradiated with laser light and at least one source follower that is irradiated twice for crystallization.

A width L of the laser light illumination for crystallization is preferably larger than a pitch d of the source followers, and is equal to the pitch d multiplied by an integer n that is not less than 3. Further, the invention is characterized in that 2 to n−1 source followers are connected together in parallel. A variation of the threshold voltage of thin-film transistors can be suppressed by combining source followers that are illuminated at different numbers of times.

Although the pitch of the source followers and the width of laser light illumination have been mentioned above, the term “pitch of the source followers” may be replaced by another term “pitch of pixels” because they are equal to each other in general.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a circuit diagram showing analog buffers of an active matrix type display device according to a first embodiment of the present invention;

FIG. 2 is a circuit diagram showing analog buffers of an active matrix type display device according to a second embodiment of the invention;

FIG. 3 is a circuit diagram showing analog buffers of an active matrix type display device according to a third embodiment of the invention;

FIG. 4 is a circuit diagram showing analog buffers of an active matrix type display device according to a fourth embodiment of the invention;

FIG. 5 is a circuit diagram showing analog buffers of an active matrix type display device according to a fifth embodiment of the invention;

FIGS. 6A and 6B are circuit diagrams showing examples of analog buffers used in a conventional active matrix type display device;

FIGS. 7A and 7B schematically illustrate laser light illumination in a conventional analog buffer manufacturing step;

FIG. 8 is a graph showing a relationship between the threshold voltage V_(th) of thin-film transistors used in the conventional analog buffers and the laser light illumination position X in a thin-film transistor manufacturing process;

FIG. 9 schematically shows the conventional active matrix type display device;

FIGS. 10A–10F shows a manufacturing process of a complementary inverter circuit; and

FIG. 11 is a graph showing an application voltage vs. transmittance characteristic of a normally-white liquid crystal device.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

First, referring to FIGS. 10A–10F, a description will be made with respect to a manufacturing process of thin-film transistors used in the present invention.

A complementary inverter circuit will be described by way of embodiment. A silicon dioxide film of 1,000–3,000 Å in thickness was formed as an undercoat oxide film on a glass substrate (low-alkali glass, quartz glass, or the like; for instance Corning 7059) by sputtering in an oxygen atmosphere. To improve the productivity, there may be used a film obtained by decomposing and depositing TEOS by plasma CVD.

Then, an amorphous silicon film was deposited at a thickness of 300–5,000 Å, preferably 500–1,000 Å by plasma CVD or LPCVD, and crystallized by being left in a reducing atmosphere of 550° C. to 600° C. for 4–48 hours. The degree of crystallization was increased by performing laser light illumination (wavelength: 308 or 248 nm) after the above step. The silicon film thus crystallized was patterned into island-like regions 1 and 2. A silicon dioxide film 3 of 700–1,500 Å in thickness was formed thereon by sputtering.

Subsequently, a film of aluminum (containing Si of 1 wt % or Sc of 0.1–0.3 wt %) of 1,000 Å to 3 μm was formed by electron beam evaporation or sputtering. A photoresist (for instance, OFPR800/30 cp produced by Tokyo Ohka Kogyo Co., Ltd.) was then formed by spin coating. Formation of an aluminum oxide film of 100–1,000 Å in thickness by anodic oxidation before the formation of the photoresist was effective in providing good adhesiveness with the photoresist and in forming a porous anodic oxide film only on the side faces in a subsequent anodic oxidation step by suppressing a leak current from the photoresist. The photoresist and the aluminum film were patterned, i.e., etched together to form gate electrodes 4 and 5 and mask films 6 and 7 (see FIG. 10A).

Anodic oxidation was performed on the resulting structure by supplying it with a current in an electrolyte, to form anodic oxide films 8 and 9 of 3,000–6,000 Å, for instance, 5,000 Å in thickness. The anodic oxidation may be performed such that a 3% to 20% acid aqueous solution of citric acid, oxalic acid, phosphoric acid, chromic acid, sulfuric acid, or the like is used and a constant voltage of 10–30 V is applied to the gate electrodes. In this embodiment, the anodic oxidation was performed for 20–40 minutes in oxalic acid of 30° C. by applying a voltage of 10 V. The thickness of the anodic oxide films 8 and 9 was controlled by the anodic oxidation time (see FIG. 10B).

After removing the mask films 6 and 7, the gate electrodes 4 and 5 were again supplied with a current in an electrolyte. An ethylene glycol solution containing tartaric acid, boric acid and nitric acid (3% to 10% in total) was used this time. A superior oxide film was obtained when the temperature of the solution was about 10° C., i.e., lower than the room temperature. As a result, barrier type anodic oxide films 10 and 11 were formed on the top and side faces of the gate electrodes 4 and 5. The thickness of the anodic oxide films 10 and 11 was proportional to the application voltage. For instance, a 2,000-Å-thick anodic oxide film was formed with an application voltage of 150 V. The thickness of the anodic oxide films 10 and 11 was determined by a necessary offset. It is preferred that the thickness be less than 3,000 Å, because a high voltage of more than 250 V is needed to produce an anodic oxide film thicker than 3,000 Å and will cause adverse effects on characteristics of the thin-film transistors. In this embodiment, the voltage was increased to 80–150 V, and a proper voltage was selected depending on a necessary thickness of the anodic oxide films 10 and 11.

It should be noted that the barrier-type anodic oxide films 10 and 11 were formed between the porous anodic oxide films 8 and 9 and the gate electrodes 4 and 5 rather than outside the porous anodic oxide films 8 and 9, though the step of forming the barrier-type anodic oxide films 10 and 11 was performed later.

Then, the insulating film 3 was etched by dry etching (or wet etching). The etching depth may be determined arbitrarily; that is, the etching may be performed until the underlying active layers 1 and 2 are exposed, or may stopped halfway. In terms of the productivity, yield and uniformess, it is desirable that the etching be performed until reaching the active layers 1 and 2. In this case, insulating films 12 and 13 having the original thickness are left in the portions of the insulating film (gate insulating film 3) covered with the anodic oxide films 8 and 9 or the gate electrodes 4 and 5 (see FIG. 10C).

Then, the anodic oxide films 8 and 9 were removed. It is preferred that the etchant be a phosphoric acid type solution, for instance, a mixed acid of phosphoric acid, acetic acid and nitric acid. With a phosphoric acid type etchant, the porous anodic oxide films 8 and 9 are etched at a rate that is more than 10 times faster than the barrier-type anodic oxide films 10 and 11. Therefore, substantially the barrier-type anodic oxide films 10 and 11 are not etched with a phosphoric acid type etchant. Thus, the gate electrodes inside the barrier-type anodic oxide films were protected.

Sources and drains were formed by implanting accelerated N-type or P-type impurity ions into the active layers 1 and 2 of the above structure. More specifically, first, with the left-hand thin-film transistor region covered with a mask 14, phosphorus ions of relatively low speed (typical acceleration voltage: 5–30 kV) were introduced by ion doping. In this embodiment, the acceleration voltage was set at 20 kV. Phosphine (PH₃) was used as a doping gas. The dose was 5×10¹⁴ to 5×10¹⁵ cm⁻². In this step, phosphorus ions cannot penetrate the insulating film 13, they were implanted into only the portions of the active region 2 whose surfaces were exposed, to form a drain 15 and a source 16 of the N-channel thin-film transistor (see FIG. 10D).

Subsequently, phosphorus ions of relatively high speed (typical acceleration voltage: 60–120 kV) were introduced also by ion doping. In this embodiment, the acceleration voltage was 90 kV, and the dose was 1×10¹³ to 5×10¹⁴ cm⁻². In this step, phosphorus ions penetrate the insulating film 13 to reach the underlying portions. However, due to the small dose, low-concentration N-channel regions 17 and 18 were formed (see FIG. 10E).

After completion of the phosphorus doping, the mask 14 was removed. In a manner similar to the above, a source 19, a drain 20, and low-concentration P-type regions 21 and 22 were formed in the P-channel thin-film transistor region with the N-channel thin-film transistor region masked this time. Impurity ions introduced into the active regions 1 and 2 were activated by illumination with KrF excimer laser light (wavelength: 248 nm; pulse width: 20 nsec).

Finally, a silicon dioxide film of 3,000–6,000 Å in thickness was formed over the entire surface as an interlayer insulating film 23 by CVD. After contact holes for the sources and drains of the thin-film transistors were formed, aluminum wiring, lines and electrodes 24-26 were formed. Further, hydrogen annealing was performed at 200° C. to 400° C. Thus, a complementary inverter circuit using the thin-film transistors was completed (see FIG. 10F).

Although the above description is directed to the inverter circuit, other circuits can be manufactured in similar manners. Further, although the above description is directed to the coplanar thin-film transistors, it can be applied to other types of thin-film transistors such as inverse-stagger type ones.

Embodiments of the invention will be described below.

FIG. 1 shows a first embodiment of the invention. In this embodiment, source followers are arranged at a pitch d, and the laser light illumination width L is equal to 3 d. Two source followers are connected to each other in parallel. Representing a source follower matrix by (1, m), the laser light is first applied to source followers (p, q), (p+1, q), (p+2, q), (p, q+1), (p+1, q+1), and (p+2, q+1).

The laser light is then moved so as to illuminate source followers (p+2, q), (p+3, q), (p+4, q), (p+2, q+1), (p+3, q+1), and (p+4, q+1).

Actually, after the first laser irradiation, the substrate mounted on a X-Y table is moved and then the second irradiation is carried out.

Further, a next laser irradiation is carried out onto the source followers (p+4, q), (P+5, q), (p+6, q), (p+4, q+1), (P+5, q+1), and (p+6, q+1).

In the above manner, the source followers (p, q), (p, q+1), (p+2, q), (p+2, q+1), (p+4, q), (p+4, q+1), (p+6, q) and (p+6, q+1) are illuminated twice with the laser light. Thus, they have the threshold voltage V_(thL) in view of FIG. 8.

On the other hand, the source followers (p+1, q), (p+1, q+1), (p+3, q), (p+3, q+1), (p+5, q), and (p+5, q+1) are illuminated only once with the laser light. Thus, they have the threshold voltage V_(thH).

By connecting to each other in parallel the source followers (p, q) and (p+1, q), the source followers (p+2, q) and (p+3, q), the source followers (p+4, q) and (p+5, q), the source followers (p+1, q+1) and (p+2, q+1), and the source followers (p+3, q+1) and (p+4, q+1) as shown in FIG. 1, the characteristics of the source followers are averaged, so that variations in the characteristics caused by the laser illumination can be reduced. In other words, in each combined source followers, one source follower has a higher crystallinity TFT while the other one has a lower crystallinity TFT.

FIG. 2 shows a second embodiment of the invention. In this embodiment, source followers are arranged at a pitch d, and the laser light illumination width L is equal to 4d. Three source followers are connected together in parallel.

The laser light is first applied to source followers (p, q), (p+1, q), (p+2, q), (p+3, q), (p, q+1), (p+1, q+1), (p+2, q+1), (p+3, q+1), (p. q+2), (p+1, q+2), (p+2, q+2) and (p+3, q+2).

The laser light is then moved so as to illuminate source followers (p+3, q), (p+4, q), (p+5, q), (p+6, q), (p+3, q+1), (p+4, q+1), (p+5, q+1), (p+6, q+1), (p+3, q+2), (p+4, q+2), (p+5, q+2) and (p+6, q+2).

Since the source followers (p, q), (p, q+1), (p, q+2), (p+3, q), (p+3, q+1), (p+3, q+2), (p+6, q), (p+6, q+1) and (p+6, q+2) are illuminated twice with the laser light, they have the threshold voltage V_(thL) (see FIG. 8).

Since the source followers (p+1, q), (p+2, q), (p+1, q+1), (p+2, q+1), (p+1, q+2), (p+2, q+2), (p+4, q), (p+5, q), (p+4, q+1), (p+5, q+1), (p+4, q+2) and (p+5, q+2) are illuminated only once with the laser light, they have the threshold voltage V_(thH) (see FIG. 8).

By connecting together in parallel the source followers (p, q), (p+1, q) and (p+2, q), the source followers (p+3, q), (p+4, q) and (p+5, q), the source followers (p+1, q+1), (p+2, q+1) and (p+3, q+1), the source followers (p+4, q+1), (p+5, q+1) and (p+6, q+1), and the source followers (p+2, q+2), (p+3, q+2) and (p+4, q+2), respectively, as shown in FIG. 2, one of the three source followers of each combination is illuminated twice with the laser light and the other two source followers are illuminated only once. By combining the source followers in the above manner, the source followers of every set are made uniform, so that variations in the characteristics caused by the laser illumination can be eliminated.

FIG. 3 shows a third embodiment of the invention. In this embodiment, source followers are arranged at a pitch d, and the laser light illumination width L is equal to 4d. Two source followers are connected in parallel to form one analog buffer where one source follower of an adjacent buffer is located between the two.

The laser light is first applied to source followers (p, q), (p+1, q), (p+2, q), (p+3, q), (p, q+1), (p+1, q+1), (p+2, q+1) and (p+3, q+1).

The laser light is then moved so as to illuminate source followers (p+3, q), (p+4, q), (p+5, q), (p+6, q), (p+3, q+1), (p+4, q+1), (p+5, q+1) and (p+6, q+1).

Since the source followers (p, q), (p, q+1), (p+3, q), (p+3, q+1), (p+6, q) and (p+6, q+1) are illuminated twice with the laser light, they have the threshold voltage V_(thL) (see FIG. 8).

Since the source followers (p+1, q), (p+2, q), (p+1, q+1), (p+2, q+1), (p+4, q), (p+5, q), (p+4, q+1) and (p+5, q+1) are illuminated only once with the laser light, they have the threshold voltage V_(thH) (see FIG. 8).

By connecting to each other in parallel the source followers (p, q) and (p+2, q), the source followers (p+1, q) and (p+3, q), the source followers (p+4, q) and (p+6, q), the source followers (p, q+1) and (p+2, q+1), the source followers (p+1, q+1) and (p+3, q+1), and the source followers (p+4, q+1) and (p+6, q+1) as shown in FIG. 3, one of the two source followers of each combination is illuminated twice with the laser light and the other source follower is illuminated only once. By combining the source followers in the above manner, the source followers of every set are made uniform, so that variations in the characteristics caused by the laser illumination can be eliminated.

FIG. 4 shows a fourth embodiment of the invention. In this embodiment, source followers are arranged at a pitch d, and the laser light illumination width L is equal to 4d. Two source followers that are located in an oblique direction are connected to each other in parallel.

The laser light is first applied to source followers (p, q), (p+1, q), (p+2, q), (p+3, q), (p, q+1), (p+1, q+1), (p+2, q+1) and (p+3, q+1).

The laser light is then moved so as to illuminate source followers (p+3, q), (p+4, q), (p+5, q), (p+6, q), (p+3, q+1), (p+4, q+1), (p+5, q+1) and (p+6, q+1).

By connecting to each other in parallel the source followers (p, q) and (p+1, q+1), the source followers (p+1, q) and (p+2, q+1), the source followers (p+2, q) and (p+3, q+1), the source followers (p+3, q) and (p+4, q+1), the source followers (p+4, q) and (p+5, q+1), and the source followers (p+5, q) and (p+6, q+1) as shown in FIG. 4, the characteristics of the source followers are averaged, so that variations in the characteristics caused by the laser illumination can be reduced.

FIG. 5 shows a fifth embodiment of the invention. In this embodiment, source followers are arranged at a pitch d, and the laser light illumination width L is equal to 4d. Three source followers located in an oblique direction are connected together in parallel.

The laser light is first applied to source followers (p, q), (p+1, q), (p+2, q), (p+3, q), (p, q+1), (p+1, q+1), (p+2, q+1), (p+3, q+1), (p. q+2), 1: (p+1, q+2), (p+2, q+2) and (p+3, q+2).

The laser light is then moved so as to illuminate source followers (p+3, q), (p+4, q), (p+5, q), (p+6, q), (p+3, q+1), (p+4, q+1), (p+5, q+1), (p+6, q+1), (p+3, q+2), (p+4, q+2), (p+5, q+2) and (p+6, q+2).

Since the source followers (p, q), (p, q+1), (p, q+2), (p+3, q), (p+3, q+1), (p+3, q+2), (p+6, q), (p+6, q+1) and (p+6, q+2) are illuminated twice with the laser light, they have the threshold voltage V_(thL) (see FIG. 8).

Since the source followers (p+1, q), (p+2, q), (p+1, q+1), (p+2, q+1), (p+1, q+2), (p+2, q+2), (p+4, q), (p+5, q), (p+4, q+1), (p+5, q+1), (p+4, q+2) and (p+5, q+2) are illuminated only once with the laser light, they have the threshold voltage V_(thH) (see FIG. 8).

By connecting together in parallel the source followers (p, q), (p+1, q+1) and (p+2, q+2), the source followers (p+1, q), (p+2, q+1) and (p+3, q+2), the source followers (p+2, q), (p+3, q+1) and (p+4, q+2), the source followers (p+3, q), (p+4, q+1) and (p+5, q+2), and the source followers (p+4, q ), (p+5, q+1) and (p+6, q+2) as shown in FIG. 5, one of the three source followers of each combination is illuminated twice with the laser light and the other two source followers are illuminated only once. By combining the source followers in the above manner, the source followers of every set are made uniform, so that variations in the characteristics caused by the laser illumination can be eliminated.

As described above, by connecting in parallel the source followers that use thin-film transistors, the invention can suppress a variation of the threshold voltage V_(th) due to overlapping of laser light illumination areas, to thereby reduce display unevenness of pixels.

While preferred embodiments of the present invention has been described, it is to be understood that the present invention should not be limited to those specific embodiments. Various modifications may be made by those ordinary skilled in the art. For example, it is possible to replace the source followers with other elements having an equivalent function, for example, op amp. 

1. An active matrix device comprising: a plurality of column lines formed over a substrate; a plurality of row lines extending over the substrate crossing said plurality of column lines to define a plurality of pixels in a matrix form; a plurality of switching elements over the substrate provided at intersections between said plurality of column lines and said plurality of row lines; a gate driver circuit over the substrate to drive said plurality of row lines; a source driver circuit over the substrate to drive said plurality of column lines, said source driver circuit including a plurality of analog buffer circuits corresponding to said plurality of column lines, wherein each of the analog buffer circuits comprises at least two circuits connected in parallel with respect to a corresponding one of the column lines, each of said circuits comprising at least one thin film transistor; and one of said at least two circuits of one of the analog buffer circuits is positioned in the same line along said column lines as one of said at least two circuits of another one of the analog buffer circuits.
 2. An active matrix device according to claim 1 wherein said at least two circuits are source follower circuits.
 3. An active matrix device according to claim 1 wherein an electrical characteristics of said at least two circuits in one of said analog buffer circuits differ from each other.
 4. An active matrix device comprising: a plurality of column lines formed over a substrate; a plurality of row lines over the substrate extending across said plurality of column lines to define a plurality of pixels in a matrix form; a plurality of switching elements over the substrate provided at intersections between said plurality of column lines and said plurality of row lines; a gate driver circuit to drive said plurality of row lines; a source driver circuit to drive said plurality of column lines, said source driver circuit including a plurality of buffer circuits formed over said substrate in a plurality of columns corresponding to said plurality of column lines, wherein each of the buffer circuits includes at least first and second circuits connected in parallel with respect to a corresponding one of the column lines, and wherein one of said first and second circuits of each of said plurality of column lines is positioned in the same column as one of said first and second circuits for another column line.
 5. An active matrix device according to claim 4 wherein each of said first and second circuits includes a thin film transistor.
 6. An active matrix device comprising: an active matrix circuit comprising a plurality of thin film transistors formed over a substrate; at least one driver circuit over the substrate to drive said active matrix circuit, said driver circuit including a plurality of buffer circuits wherein said driver circuit is operationally connected to said active matrix circuit through a plurality of signal lines extending substantially in a first direction, wherein each of the buffer circuits comprises at least first and second circuits, each of said first and second circuits comprising at least one thin film transistor, and wherein one of said first and second circuits of one of the buffer circuits is positioned in the same line along said first direction as one of the first and second circuits of another one of the buffer circuits.
 7. An active matrix device according to claim 6 wherein said first and second circuits are source follower circuits.
 8. An active matrix device according to claim 6 wherein electrical characteristics of said first and second circuits in one of said buffer circuits differ from each other.
 9. An active matrix device comprising: an active matrix circuit comprising a plurality of thin film transistors formed over a substrate; a plurality of signal lines extending in a column direction over the substrate; at least one driver circuit over the substrate to drive said active matrix circuit through said signal lines, said driver circuit including a plurality of buffer circuits; wherein each of the buffer circuits includes at least first and second circuits connected in parallel with respect to a corresponding one of the signal lines, and wherein one of said first and second circuits of each of said plurality of column lines is positioned in a same line along said signal lines as one of said first and second circuits for another column line.
 10. An active matrix device according to claim 9 wherein each of said first and second circuits includes a thin film transistor.
 11. An active matrix device according to claim 1 wherein said thin film transistor is inverse stagger type.
 12. An active matrix device according to claim 4 wherein each of said first and second thin film transistors is inverse stagger type.
 13. An active matrix device according to claim 6 wherein each of said first and second thin film transistors is inverse stagger type.
 14. An active matrix device comprising: a plurality of thin film transistors formed over a substrate; and at least one driver circuit over the substrate to drive said plurality of thin film transistors through a plurality of signal lines extending substantially in a first direction, said driver circuit including a plurality of buffer circuits connected to said signal lines, wherein each of said buffer circuits includes at least first and second circuits connected in parallel and each of said first and second circuits comprises at least one thin film transistor comprising crystallized semiconductor film, and one of the first and second circuits of one of the buffer circuits is positioned in the same line along said first direction as one of said first and second circuits of another one of the buffer circuits.
 15. An active matrix device according to claim 14 wherein the thin film transistor in said buffer circuits has an LDD structure.
 16. An active matrix device comprising: a plurality of thin film transistors formed over a substrate and a plurality of signal lines; and at least one driver circuit over the substrate to drive said active matrix circuit, said driver circuit including a plurality of buffer circuits connected to said plurality of signal lines, wherein each of said buffer circuit includes at least first and second circuits connected in parallel and each of said first and second circuits comprises at least one thin film transistor comprising crystallized semiconductor film.
 17. An active matrix device according to claim 16 wherein the thin film transistor in said buffer circuits has an LDD structure.
 18. An active matrix device comprising: a plurality of pixels; a plurality of switching elements formed over a substrate for switching said plurality of pixels; at least one driver circuit for driving said plurality of switching elements through a plurality of signal lines; a plurality of buffer circuits in said driver circuit wherein each of said buffer circuits comprises at least first and second circuits, each of which includes at least one thin film transistor formed over said substrate, and wherein the first and second circuits in each of said buffer circuits is connected in parallel with respect to a corresponding one of the signal lines, and one of the first and second circuits connected with one of said signal lines is located on an extension line of another one of the signal lines adjacent to said one of the signal lines.
 19. An active matrix device according to claim 18 wherein each of said switching elements comprises a thin film transistor.
 20. An active matrix device according to claim 18 wherein said driver circuit is a source driver circuit.
 21. An active matrix device comprising: a plurality of pixels; a plurality of switching elements formed over a substrate for switching said plurality of pixels; at least one driver circuit over said substrate for driving said plurality of switching elements through a plurality of signal lines; a plurality of buffer circuits in said driver circuit wherein said buffer circuits are connected to said plurality of signal lines, and wherein at least one of said buffer circuits which is connected to one of said signal lines is positioned on an extension line of at least said one of the signal lines and another one of the signal lines adjacent to said one of the signal lines.
 22. An active matrix device according to claim 21 wherein each of said switching elements comprises a thin film transistor.
 23. An active matrix device according to claim 21 wherein said driver circuit is a source driver circuit.
 24. An active matrix device according to claim 21 wherein each of said buffer circuits comprises at least one thin film transistor having a crystallized semiconductor film.
 25. An active matrix device comprising: a plurality of pixels; a plurality of switching elements formed over a substrate for switching said plurality of pixels; at least one driver circuit formed over said substrate for driving said plurality of switching elements through a plurality of signal lines extending substantially in a first direction; a plurality of buffer circuits in said driver circuit wherein said buffer circuits are connected to said plurality of signal lines, and wherein a portion of at least one of the buffer circuits is positioned in a same line along said first direction as a portion of at least another one of the buffer circuits.
 26. An active matrix device according to claim 25 wherein each of said switching elements comprises a thin film transistor.
 27. An active matrix device according to claim 25 wherein said driver circuit is a source driver circuit.
 28. An active matrix device according to claim 25 wherein each of said buffer circuits comprises at least one thin film transistor having a crystallized semiconductor film.
 29. An active matrix device comprising: a plurality of pixels; a plurality of switching elements formed over a substrate for switching said plurality of pixels; at least one driver circuit formed over said substrate for driving said plurality of switching elements through a plurality of signal lines extending substantially in a first direction; a plurality of buffer circuits in said driver circuit wherein said buffer circuits are connected to said plurality of signal lines, and wherein each of the buffer circuits is arranged obliquely with respect to said first direction so that a portion of at least one of the buffer circuits is positioned in a same line along said first direction as a portion of at least another one of the buffer circuits.
 30. An active matrix device according to claim 29 wherein each of said switching elements comprises a thin film transistor.
 31. An active matrix device according to claim 29 wherein said driver circuit is a source driver circuit.
 32. An active matrix device according to claim 29 wherein each of said buffer circuits comprises at least one thin film transistor having a crystallized semiconductor film. 